Oil-and water-repellent composition comprising a polymer containing fluoroalkyl monomer units and an additive copolymer

ABSTRACT

1. IN AN OIL- AND WATER-REPELLENT COMPOSITION, WHICH COMPRISES: AN OIL- AND WATER-REPELLENT POLYMER CONTAINING UNITS OF A FLUOROALKYL MONOMER AND AN ADDITIVE COPOLYMER CONTAINING 90 TO 99 WEIGHT PERCENT MONOMER UNITS HAVING THE FORMULA:   CR1R2=CR3COOR4   WHEREIN R1, R2 AND R3 REPRESENT HYDROGEN ATOMS OR METHYL GROUPS, AND R4 REPRESENTS C1-18 ALKYL GROUPS AND 1-10 WEIGHT PERCENT OF MONOMER UNITS OF THE FORMULA:   CH2=CR5CONHCH2OH   WHEREIN R5 REPRESENTS HYDROGEN OR METHYL; THE IMPROVEMENT WHICH COMPRISES: AN OIL- AND WATER-REPELLENT POLYMER CONTAINING AT LEAST 25 WEIGHT PERCENT FLUOROALKYL MONOMER UNITS HAVING C3-15 PER FLUOROALKYL GROUP AND CONTAINING 15 TO 0.1 WEIGHT PERCENT ACRYLAMIDE DERIVATIVE MONOMER UNITS SELECTED FROM THE GROUP CONSISTING OF DIACETONEACRYLAMIDE, DIACETONEMETHACRYLAMIDE, A LOWER ALKYLOL DIACETONEACRYLAMIDE AND A LOWER ALKYLOL DIACTONEMETHACRYLAMIDE.

United States Patent Office 3,849,521 Patented Nov. 19, 1974 3,849,521 OIL- AND WATER-REPELLENT COMPOSITION COMPRISING A POLYMER CONTAINING FLUOROALKYL MONOMER UNITS AND AN ADDITIVE COPOLYMER Kazusuke Kirimoto, Takao Hayashi, and Hiroaki Kojima, Yokohama, Japan, assignors to Asahi Glass Company Ltd., Tokyo, Japan No Drawing. Filed Sept. 19, 1972, Ser. No. 290,332 Int. Cl. C08f 29/22 US. Cl. 260900 6 Claims ABSTRACT OF THE DISCLOSURE An oiland water-repellent composition which comprises an oil and Water-repellent polymer containing units of a fluoroalkyl monomer and an additive copolymer containing monomer units of the formula:

wherein R R and R represent hydrogen atoms or methyl groups, and R, represents C alkyl groups; and monomer units of the formula:

CH =CR CONHCH OH wherein R represents a hydrogen atom or a methyl group.

BACKGROUND OF THE INVENTION Field of the Invention This invention relates to an oiland water-repellent composition. More particularly, it relates to an oiland Water-repellent composition containing fluoroalkyl monomer units and a specific copolymer. Heretofore, oiland water-repellent compositions have been known which contain a polymer prepared from a fiuoroalkyl monomer such as an acrylic acid or a methacrylic acid ester containing a perfluoroalkyl group, or a copolymer prepared from a polymerizable fluoroalkyl monomer and a polymerizable monomer such as an acrylic ester, maleic anhydride, chloroprene, butadiene or methylvinyl-ketone.

Description of the Prior Art Relatively expensive polymers containing perfluoroalkyl groups have been available for some time. Because of the high cost of these materials, various commercial applications have been restricted. In order to overcome the high cost of the fluoroalkyl containing polymers, various proposals for admixing fluoroalkyl polymers with the other economical additive polymers containing no fiuoroalkyl groups have been offered. For example, oiland waterrepellent compositions are known which consist of a polymer of a methacrylic acid ester containing a perfluoroalkyl group and the polymer of a polymerizable vinyl compound such as a methacrylic acid ester, butadiene and styrene. The economical polymers, which are admixed with the oiland water-repellent polymers, must not adversely affect the various physical characteristics of the resulting polymers, especially the oiland water-repellent characteristics.

Along with the oiland water-repellent characteristics of the compositions, it is important that the compositions impart durability to washing and dry-cleaning to the impregnated fabrics While preventing a deterioration in the softness and hand feelof the fabric. It is also important that the impregnated fabrics remain repellent to fatty oils, petroleum oils and water as well as repellent to the usual dirty stains such as hand stains and the like. The additive polymers added to the fiuoroalkyl containing polymer should not decrease the oiland Water-repellent characteristics and other characteristics of the resulting polymer.

Studies have shown that the conventional additive polymers added to the oiland water-repellent compositions, such as polymers of an acrylic acid ester, a methacrylic acid ester or styrene, can be used without a decrease in the oiland water-repellent characteristics of the main polymer. However, the durability, softness and stainrepellency of the impregnated fabrics decrease greatly by mixing small amounts of the additive polymers with the main polymers. A study has been conducted to find economical polymers which can be added to the oiland water-repellent polymers containing ifluoroalkyl groups without decreasing the oiland water-repellency, durability, stain-repellency and softness of fabrics impregnated with the resulting polymer.

SUMMARY OF THE INVENTION Accordingly, it is an object of this invention to provide an economical oiland Water-repellent composition which can impart excellent oiland water-repellency, durability, stain-repellency, softness and hand feeling to fabrics impregnated with the composition.

This object and other objects of this invention can be achieved by providing an oiland water-repellent composition which contains a polymer containing fluoroalkyl monomer units and a copolymer containing monomer units having the formula:

wherein R R and R represent hydrogen atoms or methyl groups, and R represents C alkyl groups; and monomer units having the formula:

CH =CR CONHCH OH wherein R represents a hydrogen atom or a methyl group.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the compositions of this invention, the monomer having the formula:

CH =CR CONHCH OH (hereinafter referred to as monomer B) can be N-methylolacrylamide and N-methylolmethacrylamide. The monomer having the formula:

(hereinafter referred to as monomer A) can be an alkyl crotonate, an alkyl acrylate or an alkyl methacrylate such as methyl acrylate, methyl methacrylate, propyl acrylate, propyl methacrylate, butyl acrylate, butyl methacrylate, isoamyl acrylate, isoamyl methacrylate, Z-ethylhexyl acrylate, Z-ethylhexyl methacrylate, octyl methacrylate, lauryl acrylate, lauryl methacrylate, cetyl acrylate, cetyl methacrylate. One or more of a broad range of monomers A and B can be selected for the preparation of a copolymer of A and B. According to the studies of this invention, it has been found that the copolymer prepared by copolymerizing N-methylolacrylamide or N-m-ethylolmethacrylamide and a C alkyl acrylate or a C alkyl methacrylate provide the most optimum results.

The ratio of monomer A to monomer B is not limited. However, better results can be obtained when the amount of monomer B is not large. It is especially preferable to use a copolymer containing from to 99% by weight units of monomer A and l10% by weight units of monomer B. It is possible to use copolymers containing greater quantities of units of monomer B, as well as copolymers containing units of other monomers with units of monomer A and monomer B. The ratio of monomer A to monomer B can be varied depending upon the type of monomers used as well as the type and amount of the oiland water-repellent polymer desired.

The amount of the additive copolymer incorporated in the oiland water-repellent composition is not limited, and can be selected depending upon the type of the oiland water-repellent polymer desired as well as upon the type of additive copolymer used. When the amount of ad ditive copolymer incorporated is too much, the oiland water-repellency of the resulting composition decreases. When the amount of additive copolymer incorporated is too small, cost reductions of the oiland water-repellent compositions are not realized. Accordingly, up to 7 parts by weight, especially 0.1-4 parts by weight, of the additive copolymer are usually combined with 1 part by weight of the oiland water-repellent polymer. The oiland waterrepellent polymers containing fiuoroalkyl monomer units can be any one of a variety of polymers including conven tional ones. In the preparation of the oiland water-repellent copolymers of this invention containing fiuoroalkyl monomers, conventional monomers can be used for the copolymerization and include unsaturated esters such as the esters of acrylic acid and methacrylic acid containing C perfluoroalkyl groups. Suitable examples include:

Non-fiuoroalkyl group containing monomers may be oopolymerized before copolymerization with fiuoroalkyl monomers to form the oiland water-repellent copolymers of this invention. Suitable non-fiuoroalkyl containing monomers include ethylene, vinylacetate, vinylfluoride, vinylidenehalide, acrylonitrile, styrene, a-methylstyrene, p-methylstyrene, acrylic acid, alkyl acrylate, methacrylic acid, alkyl methacrylate, acrylamide, methacrylamide, diacetone acrylamide, methylol diacetone acrylamide, vinylalkylethers, vinylalkylketones, butadiene, isoprene, chloroprene, glycidyl acrylate, maleic anhydride, and mixtures thereof. For example, when styrene or acrylic acid or a methacrylic acid alkyl ester is copolymerized with a fiuoroalkyl monomer according to this invention, copolymers are synthesized which have a selective solubility in certain organic solvents such as methylchloroform and trichlorotrifluoroethane. Thus, the copolymers may be advantageously used as aerosols or as organic solvent, soluble oiland water-repellent compositions.

Other types of fiuoroalkyl monomers may be used to form the oiland water-repellent compositions of this invention, such as:

CF ClCF CF CF CONHCOOCH=CH H (CF CH OCOCH= CH and CF2C1(CF2) CH OCOC(CH =CH However, it is preferable to use monomers containing perfiuoroalkyl groups. It is especially preferable in view of commercial use and availability, to use copolymerizable fiuoroalkyl monomers such as the acrylic acid esters or the methacrylic acid esters containing perfluoroalkyl groups having the formula:

wherein R, represents straight or branched chain perfiuoroalkyl groups containing C carbon atoms, R represents straight or branched chain alkylene groups containing C carbon atoms; and R represents a hydrogen atom or a methyl group. The quantity of fiuoroalkyl monomer in the total quantity of monomers used is at least 25 Weight percent, preferably 40 weight percent.

It has been found that oiland water-repellent polymers having the desired characteristics can be prepared by the polymerization of fiuoroalkyl monomer units with units of diacetoneacrylamide, diacetonemethacrylamide, or lower alkylol derivatives thereof (hereinafter referred to as acrylamide derivatives). It is especially preferable to prepare and use oiland water-repellent polymers containing vinylchloride units together with the aforementioned units.

It has been proposed to use a copolymer prepared by copolymerizing a fiuoroalkyl monomer and N-methylolacrylamide or N-methylolmethacrylamide, in order to improve the durability to washing and dry-cleaning characteristics of a polymer impregnated fabric. However, when these copolymers are used for the oiland water-repellent polymer composition, the following disadvantages have been found. The oiland water-repellency of the composition initially is decreased, although the durability is increased. Moreover, when these copolymers are applied to fabrics, the softness and hand feel of the fabrics decreases. However, these disadvantages can be overcome by using a copolymer prepared by copolymerizing a fiuoroalkyl monomer with diacetoneacrylamide, diacetonemethacrylamide, or lower alkylol derivatives thereof, if desirable, with vinylchloride.

In accordance with this invention, and oil-and Waterrepellent polymer is admixed with the additivecopolymer containing units of monomer B such as N-methylolacrylamide or N-methylolmethacrylamide and units of monomer A such as an alkyl acrylate or an alkyl methacrylate, to prepare the oiland water-repellent polymer composition. When the compositions of this invention are applied to fabrics, excellent oiland water-repellency are initially achieved, as well as a durability to washing and dry-cleaning. In addition, the softness and hand feel of the treated fabrics is not decreased. The ratio of the acrylamide derivative, e.g., diacetoneacrylamide to the fiuoroalkyl monomer is not limited and can be selected depending upon the type of fiuoroalkyl monomer and the type and amount of additive copolymer. When the amount of diacetoneacrylamide or methacrylamide employed is too great, the oiland water-repellency of the oiland water-repellent copolymer decreases. Accordingly, less than 15 weight percent of the acrylamide derivatives are usually employed. If less than 0.1 weight percent of the acrylamide derivatives are used, improvements in the durability of the impregnated fabrics is too small. When vinylchloride is copolymerized with the other monomers, from 5 to 50 weight percent of vinylchloride is usually added to the total monomer content. In accordance with this invention, the oiland water-repellent composition which has basically excellent oiland water-repellent properties is enhanced in its durability and softness by admixing the oiland water-repellent copolymer prepared by copolymerizing 0.2-l0 weight percent of an acrylamide derivative with a fiuoroalkyl monomer with the copolymer prepared by copolymerizing monomer A and monomer B. The oiland water-repellent compositions prepared as just described are different from conventional compositions and impart excellent oiland water-repellent properties to an impregnated fabric without decreasing the softness of the treated fabrics.

In order to prepare the copolymers according to this invention, various types and conditions of polymerization reactions can be selected. Any conventional method such as bulk polymerization, solution polymerization, suspension polymerization, emulsion polymerization, radiation polymerization and photopolymerization can be employed. For example, a mixture of the monomers is emulsified in water in the presence of a surface active agent, and the monomers are copolymerized with stirring. Most any polymerization initiator such as a peroxide, an azo compound or a source of ionizing radiation can be employed to initiate the polymerization. The oiland water-repellent compositions can be prepared in various forms, such as emulsions, solutions, aerosols and the like.

Solution compositions can also be prepared by dissolving the polymers in a suitable organic solvent such as acetone, methylethylketone, diethyl ether, methylchloroform, trichloroethylene, tetrachloroethylene, or chlorofluorohydrocarbons such as tetrachlorodifluoroethane, trichlorotrifluoroethane, or mixtures thereof. When the oiland water-repellent copolymer is admixed with the additive copolymer prepared from monomer A and monomer B in an organic solvent, the solution type of composition can be directly prepared.

Aerosol compositions can be prepared by packing a solution of a composition together with a propellant such as dichlorodifluoromethane, monofluorotrichloromethane, dichlorotetrafluoroethane, or the like in a can. Various organic solvents can be used to prepare the oiland wator-repellent compositions of this invention so that the composition can easily and economically be used as a solution or an aerosol. Accordingly, the oiland waterrepellent compositions of this invention can be applied by various methods depending upon the form of the compositions and the type of articles treated. For example, when the composition is an aqueous emulsion or a solution composition, the composition is coated on the surface of an article by a conventional dip coating method or any other coating method and dried. If necessary, certain cross-linking agents may be added to cure the composition. When the oiland water-repellent composition is applied as an aerosol, it is simply sprayed on an article and allowed to dry to impart satisfactory oil-, waterand stainrepellency to the treated fabric.

The oiland water-repellent compositions of this invention can be applied together with other water-repellent compositions, oil-repellent compositions, insecticides, flameproofing agents, antielectrostatic agents, dye fixing agents, shrink-proofing agents, and the like. The types of articles treated by the oiland water-repellent compositions of this invention are not limited, and can be fibrous fabrics, glass, paper, wood, leather, wool, asbestos, brick, cement, metal, metal oxides, ceramics, plastics, coating surfaces and plaster. The fibrous fabrics can be any natural fibers such as cotton, hemp, wool, silk; synthetic fibers such as polyamides, polyesters, polyvinyl alcohol, polyacrylonitrile, polyvinylchloride, polypropylene, polytetrafluoroethylene; semi-synthetic fibers such as rayon, acetate and glass fibers or mixtures thereof.

Having generally described the invention, a more complete understanding can be obtained by reference to certain specific examples, which are provided herein for purposes of illustration only and are not intended to be limiting in any manner unless otherwise specified.

In the following examples, water-repellency and oilrepellency are shown by the following measuring standards. Water-repellency is measured by the Japan Industrial Standard L-1005' spray method and the scale is shown in Table II. Oil-repellency of the composition is measured by a falling drop in n-heptane and Nujol in the ratios shown in Table The falling drop is observed over 3 minutes, and the measurements are shown by the scales in Table II.

1 TABLE I Water-repellency: Condition 100 No wetting of the surfaces. 90 Small wetting of the surfaces. -80 Visible wetting of the surfaces. 70 Partial wetting of the surfaces. 50 Full wetting of the surfaces. 0 Complete wetting of both surfaces.

In the following examples, the symbol at the right of the numbers in the tables represent a number higher than the base number.

The durability tests were conducted as follows:

In the dry-cleaning test, a fabric treated with the oiland water-repellent copolymer was stirred in a solution containing 1.0% by weight or by volume of a detergent in tetrachloroethylene at 20 C. for 30 minutes, and dried. In the washing test, the treated fabric was stirred in a solution containing 0 .3% by weight or by volume of a detergent in water at 40 C. for 7 minutes and then washed with a water flow at the rate of 600 l./hour for 15 minutes and dried. Washing was conducted in home electric washing machine. The durability of the fabric i.e., washing resistance and the dry-cleaning resistance was shown by the degree of oiland Water-repellency after washing or dry-cleaning the fabrics once and five times.

The stain-repellency tests were conducted as follows:

A 30 g. quantity of the Standard Synthetic Dry Soil having the following formula was filled in a box 30 cm. x 20 cm. x 5 cm. in size. The untreated fabrics and the treated fabrics (7.5 cm. x 5 cm. in size) were placed in the box and severely shaken for one minute to stain the fabrics. The stained fabrics were batted to remove the loose stain and the reflection density of each fabric Was measured at 450 .Stain-repellency Was calculated from the reflection density on a scale where designates the stain-repellency of the unstained fabric and 0 designates the stain-repellency of the stain untreated fabric.

STANDARD SYNTHETIC DRY SOIL Weight percent Peat 38 Cement 17 Potter soil 17 Silica 17 Activated carbon 1.75 Ferric oxide 0.5 Mineral oil 8.75

Stiffness of untreated fabric Stiffness of treated fabric Low values indicate a greater softness. The degree of softness of an untreated fabric is assigned a .value of one. Hand feel measurements are indicated by 3 Words wherein excellent means the feel of the treated fabric has the same hand feel as the untreated fabric, good means that the feel of the treated fabrics is a rather stiff feeling, and

Softness not good means that the feel of the treated fabric is quite stiff.

EXAMPLES 1-3 AND REFERENCES 14 A cotton 35-polyester 65 fabric (hereinafter referred to as C/E) was used as a test fabric. The oiland waterrepellent compositions contained the copolymer prepared from 73 weight percent of a mixture of compounds of the formula: CH =CHCOOCH CH (CF ),,CF wherein the ratio of compounds containing values of 11:5, 7, 9 and 11 is 4:3 :2:0.5, 25 weight percent vinylchloride and 2 weight percent CH =CHCONHC(CH CH COCH (diacetone acrylamide), together with the additive copolymers shown in Table III. The ratio of the main copolymer to the additive copolymer by weight was 50:50. The oiland waterrepellent compositions containing the copolymers of this invention or other copolymers were respectively diluted with water to prepare emulsions containing 1.0 weight percent of the copolymer. Each test fabric was dipped in the emulsion for one minute and squeezed between two rubber rollers until 80% saturated. The treated fabric was dried at 100 C. for 3 minutes and further heated at 150 C. for 4 minutes.

The initial oiland water-repellency, softness, hand feel and stain-repellency of the treated fabric were measured and the results are shown in Table II. As for the durability tests, oiland Water-repellency were measured after dry-cleaning and washing and the results are shown in Table IV. In Tables III and IV, the test results from a 8 In Tables III and IV:

N-MAM represents CH =CHCONHCH OH (N-methylolacrylamide);

BA represents n-butyl acrylate;

ZEHA represents Z-ethylhexylacrylate;

ZEHMA represents Z-ethylhexylmethacrylate;

St represents styrene;

C represents cotton fabric;

C/E represents cotton 65-polyester 35 fabric.

As is clear from Tables III and IV, the additive copolymer of this invention can be effectively added without reducing the characteristics of the oiland water-repellent composition. However, other additives causes a reduction of the durability and the stain-repellency of the oiland water-repellent composition.

EXAMPLES 4-5 AND REFERENCE 5 The cotton fabric and the cotton 35-p0lyester 65 fabric of Examples 1-3 were used as the test fabrics. In Example 4 and Reference 4, the oiland water-repellent composition containing the copolymer prepared from 73 weight percent of a mixture of compounds of the formula:

CH CHCOOCH CH CH CF CF (CF 2 (wherein the ratio of compounds containing values of 11:4, 6, 8 and 10 is 4:3:2:1), weight percent vinylchloride and 2 weight percent N-methylolacrylamide was used. In Example 5, the composition containing the copolymer prepared from 75 Weight percent of a mixture fabric treated with a composition containing no additive of compounds f th f l are also shown. In Table III, the ratio of monomers for the copolymerization are shown in parentheses (percent CH2TCHCOOCH2CH2 CF2 I1CF3 by weight). (wherein the ratio of compounds containing values of TABLE III Initial values of Oil Water Stain Test repelrepel- Softrepel- Additive copolymer fabric leney leney ness Hand feel lency Example 1 BA/N-MAM (95/5) C 120 90 1.18 Excellent 23 C/E 120+ 90+ 1.20 do 25 Example 2 2EHA/N-MAM (95/5). 0 120 90+ 25 C/E 120 100 1. 22

Example 3 2EHMA/N-MAM (98/2)... 0 110 90 1. 21 C/E 120 100 1. 18

Reference 1 BA polymer C 110 80+ 1.17 -.do C/E 120 100 1. 13 ....-d0 27 Reference 2 ZEHA polymer C 110 90 1.01 Excellent 39 C/E 120 90+ 1.02 ....do 36 Reference 3 Ba/St (SO/20) C 100 80+ 1. 41 33 C/E 110 90+ 1.50 30 Referencei No O 120 100 1.00 Excellent 24 C/E 120 100 1.01 ....do 27 TABLE IV Washing resistance Dry-cleaning resistance After 1 washing After 5 washings After 1 cleaning After 5 cleanings Oil- Water- Oil- Water- Oil- Water- Oil- Water- Test repelrepelrepelrepelrepelrepelrepelrepelfabric lency lency lency leney leney lency lency lency 0 90 80 70 70 120 90 120 80 Reference 1. C 70 70 50 90 50 o C/E 110 70 50 70 100 70+ 100 70 Reference 2. O 50 70 0 50 70 50 50 50 D0. C/E 80 70 0 7O 70 70 70 Reference 3. C 50 50 0 0 60 50 0 0 Do C/E 70 50 0 50 70 70 50 0 Reference C 90 80 70 50 110 80 70 Do O/E 100 80+ 80 70 120 90 80 9 n=5, 7, 9 and 11 is 4:3:2:0.5), and 25 weight percent vinylchloride was used. The oiland water-repellent compositions contained the main copolymer and the additive copolymer according to this invention or other polymers in ratios of 50:50 by weight.

In accordance with Examples 1-3, the fabric Was treated with the compositions for measurement of the oiland water-repellency. The initial oiland water-repellency,

softness, hand feel and stain-repellency of the treated fabric were measured and the results are shown in Table VI. Reference 6 involves the formulation of Example with the exclusion of an additive copolymer. The results are shown in the following tables.

(wherein the ratio of compounds containing values of n=5, 7, 9 and 11 is 4:3:2:0.5).

EXAMPLES 6-9 TABLE V Initial values of- Oil- Water- Stain Test repelrepel- Soit- Hand repel- Additive copolymer fabric lency lency ness feel lency Example 4 ZEHA/N-MAM (97/3) C 100 80+ 1.01 Fair"-.. 29 C/E 100 90+ 0.98 .do. 28

Example 5 2EHA/N-MAM (95/5) C 110 90 1.02 26 C/E 120 90+ 1.00 24 Reierence5 2EHA o1 er C 100 80 1.01 41 p ym C/E 100 90+ 1. 01

Reference 6 FA/VC (75/25) C 110 90 0.99 28 No additive (3/13 110 90+ 0. 98 26 TABLE VI Washing resistance Dry-cleaning resistance After 1 cleaning After 5 washings After 1 cleaning After 5 cleanings Oil- Water- Oil- Water- 011- Water- 011- Water- Test repelrepelrepelrepelrepelrepelrepelrepel- Iabric lency lency lency lency lency lency lency lency Exam le4 C 80 80 70 100 70 90 7 D? C/E 90 80 70 70 100 80 80 7 Example 5-. C 90 70 70 50 100 80 90 7 D0 C/E 100 80 70 70 110 80 110 7 Reference 5. C 70 70 50 50 70 70 50 5 D0 C/E 90 70 70 50 90 70 70 7 Reference 6- C 80 70 50 0 90 70 70 5 Do C/E 100 80 0 100 80 5 In Table V, N-MAM, 2EHA, C and C/ E are the same hand feel, and stain-repellency of the treated fabric are as in Table III, VC represents vinylchloride and FA represents CH CHCOOCH CH (CF CF shown in Table VII. The results of the durability tests are shown in Table VIII. Reference 7 involves the formu- 45 lation of Example 6 with the exclusion of an additive copolymer. The results are shown in the following tables.

TABLE VII Initial values of- Oil- Water- Stain Oiland water-refellent copolymer Test repelrepel- Soitrepelcomposition fabric lency lency ness Hand ieel lency OWRzFA/VC/MDAAM (70/25/5) C 120 +90 1.03 Excellent 22 BLD:BA/N-MAM 5 5 C/E 120 +90 1. 01 .d 19 OWR-FA/VC/MDAAM (/23/2). C 110 100 0. 98 o... 24 AM C/E 110 100 0.97 0. 23

O 120 +90 1. 01 2 C/E 120 100 0.99 do 24 C 110 100 0.99 do 21 110 100 0.99 .do.-- 24 120 90 1. 01 do 26 120 +90 0.99 do 25 TABLE VIII Washing resistance Dry-cleaning resistance After 1 washing After 5 washings After 1 cleaning After 5 cleanings Oil- Water- Oil- Water- Oil- Water- Oil- Water- Test repelrepelrepelrepelrepelrepelrepelrepelfabric lency lency lency lency lency lency lency lency Example 6 0 +100 80 120 +80 120 80 Do C/E 110 90 80 130 90 120 80 Example 7 O 90 +80 +70 70 90 100 +70 D0 C/E +90 +80 80 70 110 90 100 80 Example 8 C 100 80 90 +70 130 90 80 D0 C/ E 110 90 100 +70 +90 130 90 Example 9 C +90 80 80 70 120 90 120 +70 D0- C/E +90 90 90 70 120 90 120 +80 Reference 7- C 100 80 70 70 110 80 100 70 Do- 0/19 100 80 90 70 120 +80 120 70 1 1 In Table VII, N-MAM, 2EHA, BA, VC, FA are the same as stated earlier. LMA represents lauryl methacrylate; BLD represents the additive copolymer; and OWR represents the main copolymer for the oiland waterrepellent composition. MDAAM represents methyloldiacetoneacrylamide.

12 in Table XI. The oiland water-repellency results after dry-cleaning and after washing are shown in Table XII. References 9 and 10 involved the formulations of Examples 11 and 12 with the exclusion of an additive copolymer.

TABLE XI Initial values of- Oil- Water- Stain Test repelrepel- Softrepel- Additive copolymer fabnc lency lency ness Hand feel lency Example 11 BA/ZEHA/N-MMAM (30/68/2) E 130 100 0. 99 Excellent-- 21 C/E +120 100 0.07 do 19 Example 12 BA/2EHMA/N-MMAM (40/45/11) E 130 100 13 /13 +120 100 17 Reference 9 FA/DAAM of Example 11 (98/2) E 130 +90 13 (No additive). 120 90 20 Reierneee 10 FAIDAAM of Ex mple 12 (/5 1 130 100 17 (No additive) C/E 120 100 19 EXAMPLE 20 TABLE XII The oiland water-repellent composition was prepared Dry-meaning by adding the mixture of the main copolymer prepared g f g fii g f p e from 73 weight percent of a mixture of compounds of g ceamngs) 011- Water- Oil- Waterthe formula r Test repelrepelrepelrepel- CH2=CHCOOCH2CH2CH2 CFZ )n C123) 2 2o fabric lency loney leney lency (wherein the who of compounds contamrng values of Maggi E 33 $8 118 33 11:4, 6, 8 and 10 is 423:2:1), weight percent vinyl- 88 18 120 90 chloride, 2 weight percent glycidyl methacrylate and the 100 g8 g8 adrdtive copolymer prepared from 97 weight percent 38 38 110 so n-butyl acrylate and 3 weight percent N-rnethylolacryl- 90 i 8 3g amide in a 50:50 ratio by weight. The cotton fabric and the cotton 35-polyester 65 fabric of Examples 1-3 were treated with the oiland water-repellent composition in accordance with Examples 1-3. Reference 8 involves the formulation of Example 10 with the exclusion of an additive copolymer. The test results of the treated fabric are shown in Tables IX and X.

In the table, the ratio of monomers in the additive copolymer are shown in parentheses and BA, ZEHA, ZEHMA, FA, DAAM, C/E, and E are the same as stated before. N-MMAM represents CH =C(CH )CONHCH OH (N-methylolmethacrylamide) TABLE IX Initial values of- Oil- Water- Stain- Test repelrepel- Softrepelfabrlc lency leney ness Hand feel lency Example 10 C 100 80 1.05 Excellent.. Do C/E 100 90 1.69 .do 29 Reference 8... C 100 80 1.03 .do 31 Do- CIE 100 90 1.02 do 35 TABLE X Washing resistance Dry-cleaning resistance After 1 washing After 5 washings After 1 cleaning After 5 cleanings 011- Water- Oil- Water- 011- Water- 011- Water- Test; repelrepelrepelrepelrepelrepelrepelrepelfabric leney lency lency leney leney leney lency lency Example 10 O 90 8O 80 70 100 80 90 70 Do C/E 90 80 0 70 100 80 100 +70 Reference 8 C 80 70 60 100 70 80 70 Do CIE 90 80 70 70 100 80 9o 7 EXAMPLES 11-12 EXAMPLES 13-14 The copolymer prepared from FA and DAAM was used as the main copolymer for the oiland water-repellent composition. In Example 11, the copolymer prepared from 98 weight percent FA and 2 weight percent DAAM was used. In Example 12, the copolymer prepared from 95 weight percent FA and 5 weight percent DAAM was used. A 40 weight percent quantity of the main copolymer was blended with 60% of the additive copolymer shown in Table XI to prepare the oiland water-repellent composition. The cotton 35-polyester fabric and the polyester fabric (E) were used as the test fabrics. They were treated with the diluted oiland water-repellent composition (0.5 weight percent of the polymers in solution), in accordance with Examples 1-3. The initial 011- and waterrepellency, softness, hand feel and stain-repellency of the treated fabric were measured, and the results are shown The polyester fabric and the cotton 35-po1yester 65 fabric of Examples 11-12 were used as the test fabrics. In Example 13 and Reference 11, the main copolymer (OWR) prepared from weight percent of a mixture of compounds of the formula:

(wherein the ratio of compounds containing values of 11:5, 7 and 10 is 322:1), 16 weight percent styrene and 4 weight percent diacetonemethacrylamide was used. In Example 14 and Reference 12, the main copolymer (OWR) prepared from 72 weight percent 25 weight percent vinylchloride and 3 weight percent diacetonemethacrylamide was used. The oiland waterrepellent compositions were prepared by using the main copolymer and the additive copolymer shown in Table 14 Having now fully described the invention, it will be apparent to one of ordinary skill in the art that many changes and modifications can be made thereto without departing from the spirit or scope of the invention as set XIII in a ratio of 60:40 by weight. The fabric was treated 5 f th herein wlt.h a dilute and water'repiuent f Accordingly, what is claimed as new and intended to welght percent of the polymers), in accordance wlth Exb v e covered by Letters Patent ls: amples 1-3. The lnltlal 011- and water-repellency, softness, 1 I u d t u hand feel and stain-repellency of the treated fabric were o an wa er'repe em composltlon, whlch measured, and the results are shown in Table XIII. The compnes' oiland water-repellency results after dry-cleaning and an and Water-repellent P y contalmflg unlts of after washing are shown in Table XIV. a fluoroalkyl monomer and an additive copolymer TABLE xrrr Initial values 011- Water- Stain- Test repelrepel- Softrepel- Additlve copolymar fabric leney lency ness Hand feel eney Example 13 2EHAIN-MIMAM (97/3).-. E 130 100 1.12 Fair 24 C/E 130 100 1.09 do 21 Example 14 2EHAIN-N-MAM (9812).. E 130 100 1.10 Excellent-.. 22 C/E 120 +90 1.03 .do

Reference 11 OWR of Example 13 E 130 100 27 (No additive) C/E 130 100 23 Reference 12 OWR of Example 14.. E 130 100 21 (N0 additive) C/E 120 100 19 TABLE XIV containing 90 to 99 weight percent monomer units having the formula: Washing re s1stance Dry-cleaning resist- (5 waslnngs) ance (5 cleanings) 30 CR1R2= CR3COOR4 Test 33: Eggs: gg: 3325: wherein R R and R represent hydrogen atoms or tabrlc lency lency lency lency methyl groups, and R represents C alkyl groups 100 70 120 80 and 1-10 weight percent of monomer units of the 00 +70 120 .so formula: 100 so 120 90 35 00 so no 90 CH =CR CONHCH OH 90 70 120 so 3g E8 38 wherein R represents hydrogen or methyl; the im- 90 70 no so provement which comprises:

an oiland water-repellent polymer containing at least EXAMPLES 15-20 40 25 weight percent fluoroalkyl monomer units having The oiland water-repellent compositions were preper fluoroalkyl 'f cPntammg 15 to Q- pared by blending the main copolymer (OWR) prepared weight percent acrylamlde derlvatlve monomer units from 72 weight percent FA, 25 weight percent vinylchloselePted the group cnS1tmg of 'l!" ride and 3 weight percent diacetoneacrylamide with the amlde dlacetonfimethacrylamlde a lower l Y additive copolymer (BLD) prepared from 97 weight pan acetoneacrylamlde and a lower alkylol dlacetonecent 2-ethylhexylacrylate and 3 weight percent N-methylmethafry 1am1deolacrylamide in the ratio shown in Table XV (FA repre- T and f' composltlon of 91mm sents wherem the monomer having the formula:

CH =CHCOOCH CH (CF ),,CH 5O CR1R2=CR3COOR4 (wherein the ratio of fluoroalkyl compounds containing values of n=5, 7, 9 and 11 is 4:3:2305 The cotton 35- a (31-18 alkyl acrylate 01-18 alkyl methaqylate a polyester 65 fabric (C/E) was treated with the diluted alkyl crotonate and the monomer havmg the oiland water-repellent composition containing 0.5 weight m percent of the polymers, in accordance with Examples CH =CR CONHCH 0 1-3. The initial oiland water-repellency and the repel- 2 5 2 H lency after dry-cleaning and after washing of the treated is N-methylolalkylamide or N-methylolmethacrylamide. fabric were measured, and the results are shown 1n Table 3. The oiland water-repellent composition of claim 1, wherein one part by weight of said oiland water-repellent TABLE XV Washing Dry-cleaning resistance (after resistance (after 5 R no of Initial values 5 washings) cleanings) B, OWR/BLD 011- Water- 011- Water- 011- Water- (percent by repelrepelrepelrepelrepelrepelweight) lency leney lency leney lency lency Example 15... 80/20 120 100 so so 110 80 Example 16... /40 120 100 so so 100 Example 17-.- 50/50 120 100 70 +70 no 70 Example 18... 40/60 120 50 +70 90 70 Example 19..- 30/70.-. no 90 5o 70 00 50 Example 20... 20/80..... 90 so 50 70 50 50 Reference 13-. No BLD. 120 +90 70 70 50 NOTE.-OWR represents the main copolymer. BLD represents the additive copolymer.

15 polymer is admixed with'0.1-7 parts by weight of said additive copolymer.

4. The oiland water-repellent composition of claim 1, wherein said fiuoroalkyl monomer is an unsaturated ester containing a C perfluoroalkyl group.

5. The oiland water-repellent composition of claim 1, wherein the oiland water-repellent polymer is a copolymer prepared by copolymerizing said fluoroalkyl monomer with another copolymerizable monomer.

6. The oiland water-repellent composition of claim 1, wherein the copolymer contains at least 40 weight percent fiuoroalkyl monomer units, 0.2-10 weight percent of an acrylamide derivative and 5-50 weight percent vinylchloride.

References Cited UNITED STATES PATENTS PAUL LIEBERMAN, Primary Examiner 0 c. I. SEOCURO, Assistant Examiner U.S. Cl. X.R.

117135.5, 138.8 UF, 139.5 A, 140 A, 145 UT; 260-- 

1. IN AN OIL- AND WATER-REPELLENT COMPOSITION, WHICH COMPRISES: AN OIL- AND WATER-REPELLENT POLYMER CONTAINING UNITS OF A FLUOROALKYL MONOMER AND AN ADDITIVE COPOLYMER CONTAINING 90 TO 99 WEIGHT PERCENT MONOMER UNITS HAVING THE FORMULA: 